Microchip Technology
Micron Technology is a global leader in the development and manufacturing of advanced memory and storage solutions. The company's products include DRAM, NAND Flash, and NOR Flash memory, which are used in a wide range of applications, such as smartphones, computers, servers, automotive systems, and IoT devices. Micron's innovative technologies provide high-performance, energy-efficient, and reliable solutions for data-intensive applications. The company's commitment to research and development has led to numerous technological breakthroughs, including the world's first 176-layer 3D NAND Flash memory. Micron is also dedicated to sustainability, implementing eco-friendly practices in its manufacturing processes and promoting responsible sourcing of raw materials. With a focus on quality, innovation, and customer satisfaction, Micron Technology continues to be a trusted partner for businesses seeking cutting-edge memory and storage solutions.
Crystals
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Microchip Technology
Crystals
Crystal products are passive components commonly used as time or frequency references in electronic systems. They consist of a piezoelectric crystal, typically made of quartz, that exhibits the property of mechanical vibration when subjected to an applied electric field. This mechanical vibration occurs at a specific frequency, known as the resonant frequency, which is determined by the size, shape, and material properties of the crystal. To utilize a crystal as a frequency reference, an external oscillator circuit is required. This circuit provides the necessary electrical excitation to the crystal, allowing it to vibrate at its resonant frequency. The oscillator circuit is carefully designed to match the characteristics of the crystal, including its capacitance, drive voltage, and series resistance. The capacitance in the oscillator circuit is adjusted to resonate with the crystal's inherent capacitance, forming a parallel resonance circuit that allows maximum energy transfer between the crystal and the circuit. The drive voltage, which is applied across the crystal, must be within a specified range to ensure proper operation and avoid damaging the crystal element. The series resistance is carefully chosen to control the damping of the crystal's vibrations, optimizing its stability and frequency accuracy. By providing a stable and precise oscillation at the resonant frequency of the crystal, the external oscillator circuit allows the crystal to function as a reliable frequency reference. This reference signal can be used for various purposes, such as clock synchronization, frequency generation, and timing applications in digital systems, communication devices, and scientific instruments. It's worth noting that while crystal products are passive components, there are also active devices called crystal oscillators. These oscillators integrate the necessary oscillator circuitry, including amplifiers and feedback elements, into a single package. Crystal oscillators offer the convenience of a complete and self-contained solution, simplifying the design and implementation process for frequency reference applications. In summary, crystal products serve as passive components that rely on an external oscillator circuit to generate a stable and precise frequency reference. Their careful design and integration into electronic systems ensure accurate timing and reliable operation in a wide range of applications.
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